Cover Image
Read Now

Seed Dormancy Molecular Control of Its Induction and Alleviation

The appearance of the new generation in higher plants is ensured by the presence of viable seeds in the mother plant. A good number of signaling networks is necessary to provoke germination. Phytohormones play a key role in all stages of seed development, maturation, and dormancy acquisition. The do...

Full description

Bibliographic Details
Main Author: Matilla, Angel J.
Format: eBook
Language:English
Published: Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2020
Subjects:
Arf
Genomics
After-ripening
Abi3
Yuc
Germination
Monosomes
Medicago
Nitrogen Metabolism
Antioxidants
Climate Adaptation
Clade-a Pp2c Phosphatase (ahg1
Rna-seq
Carbon Metabolism
Primary Dormancy
Seed Dormancy
Asdog1
Ros
Ahg3)
Environmental Signals
Prc2
Association Mapping
Plasticity
Ethylene
Legumes
Auxin
Heme-group
Alternating Temperatures
Dna Methylation
Biology, Life Sciences / Bicssc
Oxidation
Physical Dormancy
Aba
Gaba
Dog1
Ethylene Signaling
Seed Germination
Long-lived Mrna
Pin
Dormancy Termination
Chestnut
Integuments
Seed Vigour
Gene Expression
Agl62
Research And Information: General / Bicssc
Rna Stability
Auxin And Aba
Endosperm
Online Access:
Collection: Directory of Open Access Books - Collection details see MPG.ReNa
Description
Summary:The appearance of the new generation in higher plants is ensured by the presence of viable seeds in the mother plant. A good number of signaling networks is necessary to provoke germination. Phytohormones play a key role in all stages of seed development, maturation, and dormancy acquisition. The dormancy of some seeds can be relieved through a tightly regulated process called after-ripening (AR) that occurs in viable seeds stored in a dry environment. Although ABA is directly involved in dormancy, recent data suggest that auxin also plays a preponderant role. On the other hand, the participation of reactive oxygen species (ROS) in the life of the seed is becoming increasingly confirmed. ROS accumulate at different stages of the seed's life and are correlated with a low degree of dormancy. Thus, ROS increase upon AR and dormancy release. In the last decade, the advances in the knowledge of seed life have been noteworthy. In this Special Issue, those processes regulated by DOG1, auxin, and nucleic acid modifications are updated. Likewise, new data on the effect of alternating temperatures (AT) on dormancy release are here present. On the one hand, the transcriptome patterns stimulated at AT that encompasses ethylene and ROS signaling and metabolism together with ABA degradation were also discussed. Finally, it was also suggested that changes in endogenous γ-aminobutyric acid (GABA) may prevent seed germination.
Item Description:Creative Commons (cc), https://creativecommons.org/licenses/by/4.0/
Physical Description:1 electronic resource (124 p.)
ISBN:9783039436538
books978-3-03943-654-5
9783039436545

Similar Items